A method for image processing medical self-test results receives a digital image of a self-test result generated by a self-test device. The digital image is processed using generalized curve field transforms to extract relevant geometrical features of the digital image to create a transformed image that is not distorted by distortions of the digital image. The transformed image is displayed for use in a medical diagnosis.

A flexible, multi-layered device for automatically sensing sweat biomarkers, storing and transmitting sensed data via wireless network to a computing device having software applications operable thereon for receiving and analyzing the sensed data. The device is functional in extreme conditions, including extremely hot temperatures, extremely cold temperatures, high salinity, high altitude, extreme pHs, and/or extreme pressures.

Methods and systems for monitoring workplace safety and evaluating risks is provided, the method comprising receiving signals from at least one wearable device, identifying portions of the signals corresponding to physical activities, excerpting the portions of the signals corresponding to the physical activities, and calculating risk metrics based on measurements extracted from the excerpted portions of the signals, the risk metric indicative of high risk lifting activities.

The systems and methods described herein provide a wearable sweat sensing device. The device includes a sweat patch component including a sweat biochemical sensor patch having a substrate defining a hole, at least one biochemical sensor, and a capture wick including a tip that extends through the hole, the capture wick configured to channel sweat across the at least one biochemical sensor. The sweat patch component further includes a wick downstream from the capture wick and separated from the capture wick by a gap, and electronic circuitry disposed against at least one face of the wick, wherein an electronic response of the electronic circuitry changes as sweat flows through the wick. The wearable sweat sensing device further includes an electronics module component configured to facilitate assessing hydration of a wearer based on signals from the at least one biochemical sensor and the electronic circuitry.

A display device includes: a display panel including a sensor area and a display area, where the display panel includes an upper surface and a lower surface opposite to the upper surface; and a discoloration sensor layer overlapping the sensor area, where discoloration sensor layer is disposed on one of the upper surface of the display panel and the lower surface of the display panel, and discolored when exposed to a target material. A first through portion is defined through the display panel from the upper surface to the lower surface of the display panel, and the discoloration sensor layer overlaps the first through portion.

A computer system provides biometric-based distress detection and assistance. Biometric information that is associated with an entity and audio data associated with an environment of the entity are received. A distress score is calculated based on the biometric information. The audio data is analyzed to identify one or more distress factors. In response to determining that the distress score exceeds a distress threshold and in response to identifying the one or more distress factors, a notification that the entity requires aid is transmitted to a third party. Embodiments of the present invention further include a method and program product for providing biometric-based distress detection and assistance in substantially the same manner described above.

A sensor is provided comprising a radiation emitter, a plurality of electrodes, a sensing material (transducer), and a recognition element (receptor, bioreceptor). The radiation element is configured to irradiate the sensing material, the plurality of electrodes is configured to be in electrical contact with the sensing material, and the recognition element is configured to be in contact, either directly or through an interface, with the sensing material. The sensing material is configured to receive radiation from the radiation source and interact with the target material largely through the receptor. Further, the sensing material is configured to generate measurable electrical signal upon interaction with a target molecule, when a potential is applied to the electrodes.

Disclosed is a method for correlating a biomarker in a non-blood bodily fluid with the same biomarker in the blood of an individual, including: measuring, in a first period in time, the biomarker in non-blood bodily fluid and measuring the same biomarker in the blood of the same individual to establish an R ratio of [NBBF1]/[BB1], where [NBBF1] is the biomarker concentration in non-blood bodily fluid in the first period in time, and [BB1] is the biomarker concentration in the blood in the first period in time; storing the ratio in a memory; measuring, in a second period in time, the biomarker in non-blood bodily fluid to determine [NBBF2], where [NBBF2] is the biomarker concentration in the non-blood bodily fluid in the second period in time; and correlating the measured [NBBF2] with the R ratio to generate a correlated [BB2] biomarker concentration in the blood of the individual in the second period in time. Also disclosed is a device, apparatus, and method for correlating the glucose concentration in a non-blood bodily fluid such as saliva with the glucose in the blood of an individual.

A total body water content evaluation system including a calculation device that calculates a total body moisture loss amount per unit time from a local perspiration amount (mg/cm2/min) obtained using a perspiration meter and a following formula (1),

total body moisture loss amount per unit time (mg/min)=local perspiration amount (mg/cm2/min)×correction coefficient for each measurement site×body surface area (cm2)  (1).

A smart clothing and backpack system enables a user to perform many actions. The smart clothing includes circuitry and/or is made of a conductive material enclosed in an insulation material. The smart clothing includes a set of sensors configured to detect body information. The smart clothing includes multiple electromagnets configured to adjust a size of the smart clothing. The electromagnets are configured to have an increased attraction to make the smart clothing tighter on the body of the user. The system includes a smart backpack to communicate with the smart clothing. The smart backpack includes a Radio Frequency IDentification (RFID) reader configured to detect RFID tags on or in items within the smart backpack. Many other features are able to be implemented with the smart clothing and backpack system. The smart clothing is able to include a wetsuit configured to communicate with a surfboard and/or a backpack.